posted on 2020-09-01, 14:27authored byManuel Schnabel, Elisabetta Arca, Yeyoung Ha, Caleb Stetson, Glenn Teeter, Sang-Don Han, Paul Stradins
Silicon
is a promising alloying anode for lithium-ion batteries
because of its high capacity and low cost. However, its use has been
hampered by mechanical failure arising from the large volume change
upon cycling and by an insufficiently stable solid electrolyte interphase
(SEI). SEI formation depends on the Si surface, which is often an
oxide (SiOx). In this study we compare
three different Si surfaces using Si wafers: 1.3 nm native SiOx, 1.4 nm thermally
grown SiO2, and a SiOx-free
surface. The oxide-free surface showed the worst electrochemical performance,
never exceeding 94% Coulombic efficiency (CE). It also exhibited the
thickest SEI and the highest overpotential for lithiation, which correlated
with uninhibited electrolyte reduction and the incorporation of P–F
species into the SEI. The oxide-coated surfaces performed significantly
better, demonstrating a CE above 99% beyond the second cycle, low
overpotential for lithiation, and a thinner and more stable SEI. The
oxides lower the onset potential for electrolyte reduction and yield
an SEI with fewer P–F species. However, it was found that the
CE with the native oxide surface decays from the fifth cycle onward
and correlates with a resurgence of electrolyte reduction. A 1–2
nm thermal SiO2 coating is optimum for achieving a stable
SEI that minimizes side reactions and sustains efficient cycling.